Methods and columns for nucleic acid purification

ABSTRACT

Provided are methods and columns employing a solid support comprising silica and silicon carbide for the isolation and purification of nucleic acids, and in particular, the isolation and purification of both high and low molecular weight RNA.

The present application is a divisional of U.S. patent application Ser.No. 14/696837 filed Apr. 27, 2015. This application is incorporated inits entirety by reference herein.

FIELD OF INVENTION

The present invention relates to methods and columns for thepurification and recovery of nucleic acids, and in particular, methodsand columns for the purification and recovery of high and low molecularweight RNA.

BACKGROUND

The isolation and purification of nucleic acids is a critical first stepin many research and diagnostic applications. Purified nucleic acidsmust be of high quality, such that they can be used in sensitivedownstream applications including PCR amplification, detection,sequencing, cloning and hybridization. Obtaining purified DNA or RNA isa complicated task due to the presence of large amounts of contaminatingcellular materials, (e.g. proteins and carbohydrates) present in thecomplex environments in which the nucleic acids are found, includingurine, blood, plasma, serum, saliva, feces, milk, tissues, plants, soil,yeast and fungi.

Furthermore, in addition to providing purified nucleic acids for use indownstream applications, it is also important to ensure that totalnucleic acids are isolated from a sample. This is particularly importantfor the isolation of RNA that may be used for studies involving geneexpression and gene regulation, as the quantity of a specific RNA withina cell indicates the level of expression of a particular DNA. In recentyears, the study of gene expression has increased, with gene activityand nucleic acids obtained from biological samples being used todiagnose infections or diseases including cancer, and to monitor theeffects of administered drugs, among other applications. Informationrelating to the presence and quantity of a specific RNA is critical instudying gene expression; therefore it is critical that the method ofnucleic acid isolation being employed does not favour the isolation ofcertain sizes of RNA molecules.

Many different methods for the isolation and purification of nucleicacids have been developed over the years. Traditional methods for theisolation of nucleic acids involve the use of phenol or an organicsolvent mixture containing phenol and chloroform to extract cellularmaterials followed by precipitation of the nucleic acids with alcohol.These traditional methods are problematic as they are time consuming(e.g. require multiple extraction steps), require the use of toxicchemicals and often provide low yields of nucleic acid. Further, thepurified nucleic acids can be contaminated with the organic solvents oralcohol, both of which interfere with downstream applications.

Newer methods for the purification of nucleic acids are based on solidphase purification. With solid phase purification, the nucleic acid ofinterest is bound to a solid support, while impurities such as proteinsand other non-target nucleic acids are washed away. The purified nucleicacid of interest is then eluted from the solid support. The first solidphase purification methods were based on the use of silica. Silicamaterials such as glass particles, glass powder, silica particles, glassmicrofibers, and diatomaceous earth have been used in combination withaqueous solutions of chaotropic salts to isolate DNA and RNA. Methodsfor the purification of nucleic acids using other types of supportmaterials have also been developed, including the use of silicon carbide(SiC).

SUMMARY OF INVENTION

In one aspect, provided is a column for isolating nucleic acids, thecolumn comprising: a housing comprising an inlet opening and an outletopening; and a solid support disposed within the housing between theinlet and outlet openings, the solid support comprising silica andsilicon carbide.

In one embodiment, the solid support comprises: a first layer and secondlayer, the first and second layers being in a stacked orientation; andoptionally, an intermediate layer disposed between the first and secondlayers; wherein

(a) the first layer comprises the silicon carbide and the second layercomprises the silica;

(b) the first layer comprises the silica and the second layer comprisesthe silicon carbide, or

(c) the first and second layers comprise the silica and the intermediatelayer comprises the silicon carbide;

wherein the silicon carbide is in the form of silicon carbide particlesor a slurry of silicon carbide particles, and

wherein the silica is in the form of silica particles, a slurry ofsilica particles, one or more silica membranes, or a combinationthereof. Each silica membrane can have a thickness of at least 0.5 mm.

In a further embodiment, the solid support comprises: a first layer anda second layer, the first and second layers being in a stackedorientation; and optionally, an intermediate layer disposed between thefirst and second layers; wherein

(a) the first layer comprises a plurality of silica membranes, whereinthe silicon carbide is deposited on a surface of at least one of theplurality of silica membranes and the second layer comprises at leastone silica membrane;

(b) the first layer comprises at least one silica membrane and thesecond layer comprise a plurality of silica membranes, wherein thesilicon carbide is deposited on a surface of at least one of theplurality of silica membranes;

(c) the first layer and second layer each comprise a plurality of silicamembranes, wherein the silicon carbide is deposited on a surface of atleast one of the plurality of silica membranes and the intermediatelayer comprises at least one silica membrane; or

(d) the first layer and second layer each comprise at least one silicamembrane and the intermediate layer comprises a plurality of silicamembranes, wherein the silicon carbide is deposited on a surface of atleast one of the plurality of silica membranes. Each of the silicamembranes can have a thickness of at least 0.5 mm.

In a further embodiment, the solid support comprises: a first layer anda second layer, the first and second layer being in stacked orientation;and optionally, an intermediate layer disposed between the first andsecond layers; wherein

(a) the first layer comprises at least one silica membrane, the secondlayer comprise silica particles, and the intermediate layer comprisessilicon carbide particles;

(b) the first layer comprises at least one silica membrane, the secondlayer comprise silicon carbide particles, and the intermediate layercomprises silica particles;

(c) the first layer comprises silicon carbide particles, the secondlayer comprises at least one silica membrane, and the intermediate layercomprises silica particles;

(d) the first layer comprises silica particles, the second layercomprises at least one silica membrane, and the intermediate layercomprises silicon carbide particles;

(e) the first layer and second layer each comprise silicon carbideparticles and the intermediate layer comprises silica particles; or

(f) the first layer and second layer each comprise silicon carbideparticles and the intermediate layer comprises at least one silicamembrane. Each of the silica membranes can have a thickness of at least0.5 mm.

In a further embodiment, the solid support comprises a mixture ofsilicon carbide particles and silica particles. The mixture of silicaparticles and silicon carbide particles can be provided in the form of aslurry.

In a further embodiment, the column is a spin column.

In another aspect, provided is a method for isolating nucleic acids froma sample containing nucleic acids, the method comprising the steps of:providing a solid support comprising silica and silicon carbide;contacting the sample with the solid support to bind the nucleic acid tothe solid support; and eluting the bound nucleic acids from the solidsupport.

In an embodiment, the solid support comprises a mixture of silicaparticles and silicon carbide particles. The mixture of silica particlesand silicon carbide particles can be provided as a slurry.

In a further embodiment, the solid support is provided in a column. Themethod can employ any of the columns described above.

The method can be used to isolate RNA or DNA. The isolated RNA or DNAcan be linear or branched, single or double stranded, native, modifiedor synthesized, or any fragment thereof.

BRIEF DESCRIPTION OF THE DRAWINGS

Preferred embodiments of the invention will now be described, by way ofexample, with reference to the accompanying drawings, in which:

FIG. 1 is a side view of a silica/SiC hybrid column.

FIG. 2 is a cross-sectional view (along line A-A as shown in FIG. 1) ofa first preferred embodiment of a hybrid silica/SiC column comprising asingle silica comprising layer (Hybrid A).

FIG. 3 is a cross-sectional view (along line A-A as shown in FIG. 1) ofa first preferred embodiment of a hybrid silica/SiC column comprising aplurality of silica comprising layers (Hybrid B).

FIG. 4 is a cross-sectional view (along line A-A as shown in FIG. 1) ofa second preferred embodiment of a hybrid silica/SiC column.

FIG. 5 is a cross-sectional view (along line A-A as shown in FIG. 1) ofa third preferred embodiment of a hybrid silica/SiC column (Hybrid C)with a bottom frit.

FIG. 6 is a cross-sectional view (along line A-A as shown in FIG. 1) ofa third preferred embodiment of a hybrid silica/SiC column with a topfrit.

FIG. 7 is a cross-sectional view (along line A-A as shown in FIG. 1) ofa fourth preferred embodiment of a hybrid silica/SiC column (Hybrid D).

FIG. 8 is a gel image showing the resolution of RNA that is isolatedfrom HeLa cells using a silica/SiC hybrid column (Hybrid C) and controlSiC columns and control silica columns.

FIG. 9 is a gel image showing the resolution of RNA that is isolatedfrom E. coli using a silica/SiC hybrid column (Hybrid A) and control SiCcolumns.

FIG. 10 is a gel image showing the resolution of RNA that is isolatedfrom Hamster liver cells using a silica/SiC hybrid column (Hybrid C) andcontrol SiC columns.

FIG. 11 is a gel image showing the resolution of RNA that is isolatedfrom E. coli using a silica/SiC hybrid column (Hybrid D) and control SiCcolumns and control silica columns.

FIG. 12 is a gel image showing the resolution of RNA that is isolatedfrom HeLa cells using a silica/SiC hybrid column (Hybrid B) and controlSiC columns.

Similar references are used in different figures to denote similarcomponents.

DESCRIPTION

It is known in the art that silica based purification methods tend tofavour larger RNA species and does not allow for the isolation of RNAthat is <200 nt in size. Therefore, when isolating total RNA using asilica based method, the user is actually isolating total RNA thatis >200 nt in size. This is of particular concern for gene expressionstudies as the excluded small RNAs include regulatory RNA molecules,such as microRNA (miRNA) and short interfering RNA (siRNA), as well astRNA and 5S rRNA. These small RNA molecules have attracted muchattention in recent years for their role in regulating gene expressionin signaling pathways, cell death, organ development and metabolism.Moreover, increasing evidence has suggested the involvement of smallRNAs in human disease including cancer pathogenesis and viral-relatedinfections.

In contrast to silica based purification methods, silicon carbide basedpurification methods have been shown to exhibit no size-bias when usedfor RNA purification. However, silicon carbide (SiC) based purificationmethods have been shown to have a lower capacity as compared to silicabased methods for recovering RNA.

It has now been surprisingly found that using silica and SiC incombination results in an overall higher yield of nucleic acids of allsizes, including small RNAs, as compared to prior art purificationmethods using silica or SiC. In particular, through the use of a hybridsolid support comprising both silica and SiC, it has been surprisinglyfound that a higher yield of total RNA was obtained when compared to theuse of solid supports consisting of silica or SiC alone. This surprisingresult was particularly evident in the increased amount of small RNAthat was recovered using the hybrid solid support as compared to theamount of small RNA recovered using SiC alone. This was an unexpectedresult as it is known that silica does not isolate the small RNAmolecules; therefore the use of silica and SiC together would not beexpected to recover greater amounts of small RNA (e.g. <200 nt) than theuse of SiC alone.

Silica/SiC Solid Supports and Columns

In one embodiment, disclosed is a solid support for the isolation andpurification of nucleic acids, the solid support comprising silica andSiC. As used herein, the term “nucleic acids” refers to RNA or DNA thatis linear or branched; single or double stranded; native, modified orsynthesized; or any fragment thereof.

The solid support can be prepared using different types of silicamaterials, including, but not limited to: glass particles, glass powder,silica particles, glass microfibers, diatomaceous earth, silica sand,silica gel and mixtures thereof. Further, the solid support can beprepared using silica materials in various forms. The silica materialscan be used in a slurry or bead-based format. In other embodiments, thesilica materials may be formed or incorporated into structures, such assilica membranes, silica impregnated or coated filters, and silicacoated magnetic beads.

The solid support can be prepared using the typical industrialpreparation of SiC, which is composed of about 97.8% silicon carbide andsmall amounts of silicon dioxide, silicon, iron, aluminum and carbon.SiC is available in a variety of grit sizes or grades, with each gradehaving a different average particle size. While the solid support may beprepared using any grade of SiC, a preferred grit size is 2500. The SiCcan be used in a slurry format. In other embodiments, the SiC can beapplied directly onto to the silica materials. For example, SiCparticles can be applied to a surface of a silica membrane by spraying.

In one embodiment, the solid support can comprise a mixture of silicaparticles and SiC particles provided in a slurry format. The slurry canbe made in an appropriate liquid containing both the silica particlesand SiC particles. The silica particles and SiC particles can be mixedin various different ratios, with a preferred ratio being a 1:1 weightratio. In use, the slurry can be combined with an aqueous solutioncontaining nucleic acids. The slurry is thoroughly mixed with theaqueous solution to allow the nucleic acids to bind to the silicaparticles and SiC particles. The solid support with the bound nucleicacids can then be separated from the liquid phase through pelleting bycentrifugation, or by passing the silica particles and the SiC particlesthrough a solid support column or through gravity settling. Once thebound particles have been separated, the nucleic acids can be elutedfrom the silica particles and the SiC particles using an appropriateelution solution.

In another embodiment, the solid support can be provided within achromatography column to provide a hybrid silica/SiC column. The columnmay be any size, from small spin columns all the way to largechromatography columns operating through the use of gravity or pumps. Inuse, an aqueous solution comprising the nucleic acids to be isolated canbe introduced into the column. As the sample travels through the column,the nucleic acids will come into contact to the solid support andselectively bind to the silica and SiC. The bound nucleic acids can beeluted from the solid support using an appropriate elution solution andcollected for downstream applications.

In a further embodiment, the solid support is provided in a spin column,for example, spin column 10 as shown in FIG. 1. The spin column 10 cancomprise an elongated housing 12 having an upper portion 14 and a lowerportion 16. An inlet opening 18 is defined in the upper portion 14 ofthe housing 12 and is configured to receive a sample containing nucleicacids. An outlet opening 20 is defined in the lower portion 16 of thehousing 12 and is configured to allow effluent and eluted nucleic acidsto exit the housing. The silica materials and SiC particles comprisingthe solid support may be arranged in various configurations within thecolumn housing.

In one embodiment, the solid support can be comprised of one or morelayers comprising silica and one or more layers comprising SiC. Thesilica comprising layers and SiC comprising layers can be arranged inthe column in any configuration, including in an alternating stackedfashion. The layers may be spaced apart from one another through theinclusion of other solid support media and/or one or more columnfittings such as O-rings, filters, and frits. The SiC comprising layerscan include SiC particles or a slurry of SiC particles. The silicacomprising layers can comprise silica particles, a slurry of silicaparticles, one or more silica membranes, or a combination thereof.

In a first preferred embodiment, as seen in FIGS. 2 and 3 (Hybrid A andB), the hybrid silica/SiC column 10 comprises a solid support comprisinga first layer 32 and a second layer 34. The first and second layers 32,34 have a stacked arrangement when the column 10 is in a verticalorientation as shown in FIGS. 2 and 3. The first layer 32 comprises theSiC and the second layer 34 comprises the silica material. It will beappreciated that the first layer 32 may be composed of varying amountsof SiC depending on the size of the column. The second layer 34 may becomposed of multiple layers of silica material.

In a second preferred embodiment, as seen in FIG. 4, the hybridsilica/SiC column 10 comprises a solid support comprising a first layer32 and a second layer 34. The first and second layers 32, 34 have astacked arrangement when the column 10 is in a vertical orientation asshown in FIG. 4. The first layer 32 comprises the silica materials andthe second layer 34 comprises the SiC. It will be appreciated that thefirst layer 32 may be composed of multiple layers of silica materials.The second layer 34 may be composed of varying amounts of SiC dependingon the size of the column.

The solid support may further comprise an intermediate layer 36 disposedbetween the first and second layers 32, 34. FIGS. 5 (Hybrid A) and 6illustrate a third preferred embodiment of a hybrid silica/SiC column.The solid support comprises a first layer 32, a second layer 34 and anintermediate layer 36 disposed between the first and second layers 32,34. In a third preferred embodiment, the first layer 32 and the secondlayer 34 each comprise the silica material and the intermediate layer 36comprises the SiC. It will be appreciated that each of the first andsecond layers 32, 34 may be composed of multiple layers of silicamaterial. The intermediate layer 36 may be composed of varying amountsof SiC depending on the size of the column.

It will be appreciated that the solid support may combine the silicamaterial and SiC in different forms and different arrangements. Forexample, in one embodiment, the first layer can comprise at least onesilica membrane, the second layer can comprise silica particles, and theintermediate layer comprises SiC particles. In another embodiment, thefirst layer can comprise at least one silica membrane, the second layercan comprise SiC particles, and the intermediate layer can comprisesilica particles. In another embodiment, the first layer can compriseSiC particles, the second layer can comprise at least one silicamembrane, and the intermediate layer can comprise silica particles. Inanother embodiment, the first layer can comprise silica particles, thesecond layer can comprises at least one silica membrane, and theintermediate layer can comprises SiC particles. In another embodiment,the first layer and second layer each can comprise SiC particles and theintermediate layer comprises silica particles. In another embodiment,the first layer and second layer each can comprise SiC particles and theintermediate layer comprises at least one silica membrane.

In the layered embodiments described herein, each of the silicacomprising layers may be comprised of silica particles, a slurry ofsilica particles, one or more silica membranes or any combinationthereof. In embodiments where the silica comprising layer is comprisedof a plurality of silica membranes (e.g. the silica membranes being in astacked arrangement), each of the silica membranes may be of varyingthickness. The thickness of each silica membrane is preferably at least0.5 mm. In some embodiments, the silica membrane may have a thicknessgreater than 0.5 mm, including thicknesses of 1 mm and 3 mm. It will beappreciated that each of the silica comprising layers may comprisedifferent numbers of silica membranes and the silica membranes may be ofdifferent thicknesses. Further in these layered embodiments, the SiCcomprising layers may be comprised of SiC particles or a slurry of SiCparticles. It will be appreciated that different amounts and differentgrit sizes of SiC particles can be used in combination with the one ormore silica comprising layers to provide the solid support.

To prepare a hybrid silica/SiC column comprising a solid support havinga layered arrangement, the silica materials and SiC can be packedsequentially into a chromatography column, and more preferably aconventional spin column. The spin column may have a volume of about 1.0ml and more preferably, of about 0.9 ml. The amount of SiC particlespacked into the spin column is preferably about 100 mg. However, largerand smaller amounts of SiC can also be used depending on the size of thecolumn. Depending on the arrangement of the silica comprising layer (orlayers) and the choice of silica materials (e.g. use of silica particlesversus silica membranes), the column can be fitted with an appropriatebottom frit material (such as for example, filter membranes from Porex,Fairburn, USA or Whatman filter papers from Sigma-Aldrich, St. Louis,USA) to prevent the loss of the support materials out the bottom of thecolumn. In some embodiments, the column may further be provided with atop frit material (such as for example, filter membranes from Porex,Fairburn, USA or Whatman filter papers from Sigma-Aldrich, St. Louis,USA). The column may further be provided with top and/or bottom O-ringsto prevent the silica comprising layers and SiC comprising layers fromshifting within the column. O-rings can also be included to preventliquid from channelling along the inner wall of the spin column.

As seen in FIGS. 2 (Hybrid A) and 3 (Hybrid B), a first preferredembodiment of the hybrid silica/SiC column 10 can be prepared by placinga bottom frit material 38, followed by a bottom O-ring 40, into aconventional spin column housing 12. The first layer 32 of the solidsupport is formed by placing SiC particles over the bottom frit material38. The second layer 34 of the solid support is formed by placing atleast one silica comprising layer (as shown in FIG. 2) or a plurality ofsilica comprising layers (as shown in FIG. 3) over the SiC particles.The second layer 34 can optionally be covered with a top frit materialor a top O-ring.

As seen in FIG. 4, a second preferred embodiment of the hybridsilica/SiC column 10 can be prepared by placing a bottom frit material38 into a conventional spin column housing 12. The first layer 32 of thesolid support is formed by placing at least one silica comprising layerover bottom frit material 38. The second layer 34 of the solid supportis then formed by placing SiC particles over the silica comprisinglayer. As seen in FIG. 4, the SiC particles can be contained within abottom O-ring 40. A top frit material 42 can then be placed over the SiCparticles.

As seen in FIG. 5 (Hybrid C), a third preferred embodiment of the hybridsilica/SiC column 10 can be prepared by placing a bottom frit material38 into a conventional spin column housing 12. The first layer 32 isformed by placing at least one silica comprising layer over the bottomfrit material 38. The intermediate layer 36 is formed by placing SiCparticles on top of the silica comprising layer. As seen in FIG. 5, theSiC particles can be contained within a bottom O-ring 40. The secondlayer 34 is formed by placing at least one upper silica comprising layerover the SiC particles. The second layer 34 can be covered with topO-ring 44 or a top frit material 42 (not shown).

As seen in FIG. 6, a third preferred embodiment of the hybrid silica/SiCcolumn 10 can be prepared using at least one lower silica comprisinglayer in the form of a silica membrane as the first layer 32. In thisembodiment, no bottom frit is required. Next, the SiC particles can beplaced on top of the silica comprising layer to form the intermediatelayer 36. As seen in FIG. 6, the SiC particles can be contained within abottom O-ring 40. The second layer 34 is formed by placing at least oneupper silica comprising layer over the SiC particles. The second layer34 can be covered with a top frit material 42.

In a fourth preferred embodiment, the hybrid silica/SiC column cancomprise a solid support comprising one or more silica membranes havingSiC deposited on a surface of each of the silica membranes. The SiCtreated silica membrane can be prepared by spraying at least one surfaceof the silica membrane with a slurry of SiC particles, and morepreferably, SiC particles having a grit size of 2500. The SiC slurryused to treat the silica membrane can be about 5% to 100% w/w. Thesilica membranes can be sprayed with different amounts of SiC. The SiCtreated silica membranes may comprise about 0.1 mg to about 10 mg of SiCper mm², more preferably about 0.5 mg to about 5 mg per mm², and moreeven preferably, about 0.7 mg to about 3 mg per mm². The SiC treatedsilica membranes can be of varying thickness, and are preferably atleast 0.5 mm thick.

The hybrid silica/SiC column can be prepared by placing a bottom fritmaterial into a conventional spin column, followed by two SiC treatedsilica membranes, stacked on top of one another, such that the SiCtreated surfaces of the silica membranes are facing towards the insideof the stack and the untreated surfaces of the silica membranes arefacing outward. In further embodiments, the stacked SiC treated silicamembranes can be combined with one or more silica comprising layers. Thesilica comprising layers may be comprised of silica particles, a slurryof silica particles, or one or more silica membranes or a combinationthereof. In embodiments where the silica comprising layer is comprisedof a plurality of silica membranes, each of the silica membranes may beof varying thickness. The thickness of each silica membrane ispreferably at least 0.5 mm. It will be appreciated that each of silicacomprising layers may comprise different numbers of silica membranes andthe silica membranes may be of different thicknesses.

The stacked SiC treated silica membranes and the one or more silicacomprising layers can be arranged in any number of differentconfigurations within the column, including in an alternating stackedorientation and in a sandwiched configuration. For example, in oneembodiment, the hybrid silica/SiC column can comprise a solid supportcomprising a first layer 32 and a second layer 34 as shown in FIG. 7(Hybrid D). The first and second layers are in a stacked arrangementwhen the column is vertically oriented along its longitudinal axis. Thefirst layer 32 can be composed of at least one silica comprising layerand the second layer 34 can be composed of the stacked SiC treatedsilica membranes. In another embodiment, the first layer can be composedof the stacked SiC treated silica membranes and the second layer can becomposed of at least one silica comprising layer.

In a further embodiment, the hybrid silica/SiC column can comprise asolid support comprising a first layer and a second layer and anintermediate layer disposed between the first and second layers. Thefirst layer, intermediate layer and second layer having a stackedarrangement when the column is vertically oriented relative to itslongitudinal axis. Each of the first and second layers can be composedof at least one silica comprising layer. The intermediate layer can becomposed of the stacked SiC treated silica membranes. In anotherembodiment, each of the first and second layers can be composed ofstacked SiC treated silica membranes and the intermediate layer can becomposed of at least one silica comprising layer.

In a fifth preferred embodiment, the hybrid silica/SiC column comprisesa solid support comprising silica particles and SiC particles packedinto a conventional spin column. The hybrid silica/SiC column can beprepared using a slurry of SiC particles and liquid (1:1 ratio byweight) and an slurry of silica particles and liquid (1:1 ratio byweight). In one embodiment, the hybrid silica/SiC column is prepared byfirst placing a bottom frit into the column, followed by 50% by weightSiC particles and then topped with 50% by weight silica particles for atotal of 100 mg of resin in the column. A top frit material is thenplaced on top of the packed resins. In another embodiment, the hybridsilica/SiC column is prepared by first placing a bottom frit into thecolumn, followed by 50% silica particle, and then topped with 50% SiCfor a total of 100 mg of resin in the column. A top frit material isthen placed on top of the packed resins. The hybrid silica/SiC columnscan be prepared using any grade of SiC, with a preferred grit size being2500. A preferred particle size for the silica particles is at least 2microns. It will be appreciated that the hybrid silica/SiC columns canbe prepared using different ratios of SiC particles: silica particles,and can also be made by adding at least one silica comprising layer (asdescribed above) above and/or below the packed resins in the column.

In a sixth preferred embodiment, the hybrid silica/SiC column comprisesa solid support comprising a mixture of silica particles and SiCparticles. The mixture can be formed using the silica particles and theSiC particles as described above. A slurry can be made in an appropriateliquid which contains both SiC particles and silica particles. The SiCand silica particles can be mixed in different ratios. The slurrymixture can then be packed into a conventional spin column fitted with abottom frit, and a top frit can be placed on top of the combined SiC andsilica slurry mixture. In another embodiment, the slurry can be packedinto a column by stabilizing the slurry using any supporting matrixknown in the art, including gel and polymer matrices. In anotherpreferred embodiment these hybrid columns made with a mixture of SiC andsilica particles can also contain additional layers of silica membraneeither above the hybrid resin, below the hybrid resin, or both above andbelow the hybrid resin.

Methods for the Isolation and Purification of Nucleic Acids

In another embodiment, disclosed is a method for isolating nucleic acidsfrom a sample containing nucleic acids. The method can comprise thesteps of: providing a solid support comprising silica and siliconcarbide; contacting the sample with the solid support to bind thenucleic acid to the solid support; and eluting the bound nucleic acidsfrom the solid support.

The method can be used to isolate nucleic acids from different types ofbiological samples, including but not limited to blood, saliva, plasma,serum, urine, sputum, stool, cerebral spinal fluid, cells, tissues,plants, fungi, bacteria and virus. The biological samples can beprepared using conventional homogenization and lysis methods (asappropriate to the sample type) to provide an aqueous solutioncontaining the nucleic acids to be recovered and which is substantiallyfree of cellular debris. Exemplary methods for the preparation of tissueand cells samples are set out in the Examples section below. Thedisclosed method can also be used to isolate nucleic acids fromsolutions including enzymatic reactions, melted gel slices, or any othernucleic acid-containing solution.

The method can be carried out using any of the solid supports describedabove. In one embodiment, the solid support can comprise a slurry ofsilica particles and SiC particles, preferably in a 1:1 ratio by weight.The slurry mixture can be added to an aqueous solution containingnucleic acids (for example, a lysate solution mixed with a suitableamount of ethanol). The slurry is thoroughly mixed with the aqueoussolution to allow the nucleic acids to bind to the silica particles andSiC particles under low salt conditions and slightly acidic to neutralpH conditions of about pH 4-7. The solid support with the bound nucleicacids can then be separated from the liquid phase through pelleting bycentrifugation, or by passing the silica particles and the SiC particlesthrough a solid support column or through gravity settling. Once thebound particles have been separated, the nucleic acids can be elutedfrom the silica particles and the SiC particles using an appropriate lowsalt elution solution (for example, 1-10 mM Tris.HCl) under slightlybasic to neutral pH conditions of about pH 7-9 and collected fordownstream applications.

In another embodiment, the method can be carried out using any of thehybrid silica/SiC columns described above. In a preferred embodiment,the method is carried out using a hybrid silica/SiC spin column andconventional spin column methodology for recovering the nucleic acids.For example, an aqueous solution containing nucleic acids (for example,a lysate solution mixed with a suitable amount of ethanol) can be loadedinto the spin column using a pipette. The spin column is centrifugedcausing the sample to travel through the spin column. The nucleic acidscontained in the sample will come into contact to the solid support andselectively bind to the silica and SiC under slightly acidic to neutralpH conditions of about pH 4-7. The resulting column flow-through can bediscarded. The spin column can then be washed with an appropriate lowsalt wash solution (for example, 1-100 mM Tris.HCl, MOPS or HEPES with0-100 mM NaCl or KCl) to remove materials not selectively bound to thesolid support. The bound nucleic acids can then be eluted from the solidsupport using an appropriate low salt elution solution (for example,1-10 mM Tris.HCl) under slightly basic to neutral pH conditions of aboutpH 7-9 and collected for downstream applications.

EXAMPLES Example 1

A hybrid column (Hybrid C Having the Solid Support arrangement shown inFIG. 5) was tested for its ability to isolate total RNA from HeLa celllysate, and the performance was compared to control columns of SiC aloneand silica alone. The hybrid column contain a bottom frit, followed by asingle layer of 1 mm silica membrane, 95 mg of silicon carbide resingrit size 2500, and another single layer of 1 mm silica membrane on topof the SiC resin. The control silica columns contained 4 sheets ofsilica membrane with a thickness of 1 mm each, and the control SiCcolumn contained a bottom frit, 95 mg of 100% SiC slurry with a gritsize of 2500, followed by a top frit.

One large confluent plate of HeLa cells was used for the input, and 9.1mL of the Lysis Solution from Norgen's Total RNA Purification Kit(Cat#17200, Norgen, Thorold, Canada) was added to the cells and it wasvortexed to mix. Next, 5.2 mL of ethanol was added, and again it wasvortexed to mix. Next, 550 μL of the lysate was applied to each of thecolumns (3×Hybrid C, 3×Silica Control, 3×SiC control). The columns werecentrifuged for 1 minute at 14,000 rpm for binding of the nucleic acids.Next, 400 μL of Wash Solution from Norgen's Total RNA Purification Kit(Cat#17200, Norgen, Thorold, Canada) was added to each column, and thecolumns were spun at 14,000 rpm for 1 minute. The wash step was repeatedtwo more times for a total of 3 washes. The columns were then spun emptyfor 2 minutes at 14,000 rpm in order to dry the columns. Lastly, thebound total RNA was eluted from the columns using 50 μL of the ElutionSolution from the Total RNA Purification Kit (Cat#17200, Norgen,Thorold, Canada).

For visual analysis, 5 μL of each of the elutions was run on a 1×MOPS,1.5% formaldehyde-agarose gel (150V for 30 minutes). The gel image canbe seen in FIG. 8, indicating that the total RNA profile could beisolated using the hybrid columns, which is similar to the SiC controlcolumn (isolated both large and small RNA). Also, as seen from the gel,the overall yield of total RNA when using the hybrid column was muchhigher than when the SiC control column or silica control column wasused.

To further analyze the yield, the RNA was quantified using a GE NanovuePlus Nanodrop. This analysis revealed the superior performance of thehybrid column. As it can be seen in Table 1, the average yield using thehybrid column was 19.24 μg, whereas the yield using the control silicacolumn was 8.79 μg and the yield using the control SiC column was 13.62μg.

TABLE 1 Column Type Average Yield (μg) Standard Deviation Silica Control13.62 0.20 SiC Control 8.79 1.29 Hybrid C 19.24 0.50

Example 2

A hybrid column (Hybrid A having the solid support arrangement shown inFIG. 2) was tested for its ability to isolate total RNA from E. colilysate, and the performance was compared to control columns of SiCalone. The hybrid columns were made by placing a bottom frit into acolumn, and then adding 95 mg of 100% SiC slurry with a grit size of2500, followed by a single silica membrane of 3 mm thickness. Thecontrol SiC columns contained a bottom frit, 100 mg of 100% SiC slurrywith a grit size of 2500, followed by a top frit.

For each isolation, 1 mL of E. coli culture lysate was used as theinput. Initially, 20 mL of culture was spun down, and the pellet wasresuspended in 2 mL of 1 mg/mL lysozyme and then incubated at roomtemperature for 5 minutes. Next, 7 mL of the Lysis Solution fromNorgen's Total RNA Purification Kit (Cat#17200, Norgen, Thorold, Canada)was added to the lysate and it was vortexed to mix. Next, 4 mL ofethanol was added, and again it was vortexed to mix. Next, 1 mL of thelysate was applied to each of the columns (3×SiC Control, 3×Hybrid AColumn). The columns were centrifuged for 1 minute at 14,000 rpm forbinding of the nucleic acids. Next, 400 μL of Wash Solution fromNorgen's Total RNA Purification Kit (Cat#17200, Norgen, Thorold, Canada)was added to each column, and the columns were spun at 14,000 rpm for 1minute. The wash step was repeated two more times for a total of 3washes. The columns were then spun empty for 2 minutes at 14,000 rpm inorder to dry the columns. Lastly, the bound total RNA was eluted fromthe columns using 50 μL of the Elution Solution from the Total RNAPurification Kit (Cat#17200, Norgen, Thorold, Canada).

For visual analysis, 5 μL of each of the elutions was run on a 1×MOPS,1.5% formaldehyde-agarose gel (150V for 30 minutes). The gel image canbe seen in FIG. 9, indicating that the total RNA profile could beisolated using the hybrid columns, which is similar to the SiC controlcolumn (isolated both large and small RNA). In addition, the gelindicates that the overall yield of total RNA isolated using the hybridcolumn was much higher than when the SiC control column was used.

To further analyze the yield, the RNA was quantified using a GE NanovuePlus Nanodrop. This analysis revealed the superior performance of thehybrid column. As it can be seen in Table 2, the average yield using thehybrid column was 31.0 μg, whereas the yield using the control SiCcolumn was 21.4 μg.

TABLE 2 Column Type Average Yield (μg) Standard Deviation SiC Control21.4 1.4 Hybrid A 31.0 2.8

Example 3

A hybrid column (Hybrid C) having the solid support arrangement shown inFIG. 5) was tested for its ability to isolate total RNA from Hamsterliver lysate, and the performance was compared to control columns of SiCalone. The hybrid column contained a bottom frit, followed by a singlelayer of 1 mm silica membrane, 95 mg of silicon carbide resin grit size2500, and another single layer of 1 mm silica membrane on top of the SiCresin. The control SiC columns contained a bottom frit, 95 mg of 100%SiC slurry with a grit size of 2500, followed by a top frit.

Ten mg of Hamster liver was used for the input, and was ground into afine powder using liquid nitrogen. To prepare the lysate 4.8 mL of theLysis Solution from Norgen's Total RNA Purification Kit (Cat#17200,Norgen, Thorold, Canada) was added to the cells and it was vortexed tomix. Next, the lysate was spun down to pellet insoluble materials, andthe supernatant was aliquoted into 300 μL aliquots. Next, 300 μL ofethanol was added, and again it was vortexed to mix. Next, 600 μL of thelysate was applied to each of the columns (3×Hybrid C, 3×SiC control).The columns were centrifuged for 1 minute at 14,000 rpm for binding ofthe nucleic acids. Next, 400 μL of Wash Solution from Norgen's Total RNAPurification Kit (Cat#17200, Norgen, Thorold, Canada) was added to eachcolumn, and the columns were spun at 14,000 rpm for 1 minute. The washstep was repeated two more times for a total of 3 washes. The columnswere then spun empty for 2 minutes at 14,000 rpm in order to dry thecolumns. Lastly, the bound total RNA was eluted from the columns using50 μL of the Elution Solution from the Total RNA Purification Kit(Cat#17200, Norgen, Thorold, Canada).

For visual analysis, 5 μL of each of the elutions was run on a 1×MOPS,1.5% formaldehyde-agarose gel (150V for 30 minutes). The gel image canbe seen in FIG. 10, indicating that the total RNA profile could beisolated using the hybrid columns, which is similar to the SiC controlcolumn (isolated both large and small RNA).

To further analyze the yield, the RNA was quantified using a GE NanovuePlus Nanodrop. This analysis revealed the superior performance of thehybrid column. As it can be seen in Table 3, the average yield using thehybrid column was 44.8 μg, whereas the yield using the control SiCcolumn was 21.2 μg.

TABLE 3 Column Type Average Yield (μg) Standard Deviation Hybrid C 44.81.9 Control SiC 21.2 7.1

Example 4

A different hybrid column was tested for its ability to isolate totalRNA from E. coli lysate. The hybrid column (Hybrid D having the solidsupport arrangement shown in FIG. 7) contained silica sheets sprayedwith SiC. To make these sheets, 1 mm thick silica membranes are sprayedwith a 100% slurry of SiC with a grit size of 2500. The silica issprayed in such a way that the SiC is deposited evenly on the silicamembrane and not in clumps. Two such sprayed sheets are then placedtogether with the SiC layers facing inwards. The column is then made byplacing a bottom frit into a column, then placing 2 sheets of 1 mm thicksilica membrane into the column, and then placing the 2 layers of silicasheets that have been sprayed with SiC. Each of these columns containsan average of 23 mg of SiC. The control silica columns contained 4sheets of silica membrane with a thickness of 1 mm each, and the controlSiC columns contained a bottom frit, 100 mg of 100% SiC slurry with agrit size of 2500, followed by a top frit were also used.

For each isolation, 0.5 mL of E. coli culture was used as the input.Initially, 7.5 mL of culture was spun down, and the pellet wasresuspended in 2 mg/mL of lysozyme and then incubated at roomtemperature for 5 minutes. Next, 4.5 mL of the Lysis Solution fromNorgen's Total RNA Purification Kit (Cat#17200, Norgen, Thorold, Canada)was added to the lysate and it was vortexed to mix. Next, 3 mL ofethanol was added, and again it was vortexed to mix. Next, 600 μL of thelysate was applied to each of the columns (3×Hybrid D, 3×silica control,3×SiC control). The columns were centrifuged for 1 minute at 14,000 rpmfor binding of the nucleic acids. Next, the columns were washed 3 timesusing Wash Solution from Norgen's Total RNA Purification Kit (Cat#17200,Norgen, Thorold, Canada). The columns were then spun empty for 2 minutesat 14,000 rpm in order to dry the columns. Lastly, the bound total RNAwas eluted from the columns using 50 μL of the Elution Solution from theTotal RNA Purification Kit (Cat#17200, Norgen, Thorold, Canada).

For visual analysis, 5 μL of each of the elutions was run on a 1×MOPS,1.5% formaldehyde-agarose gel (150V for 30 minutes). The gel image canbe seen in FIG. 11, indicating that the total RNA profile could beisolated using the hybrid column (isolated both large and small RNA).

To further analyze the yield, the RNA was quantified using a GE NanovuePlus Nanodrop. This analysis revealed the superior performance of thehybrid column. As it can be seen in Table 4, the average yield usingHybrid Column D was 19.97, whereas the yield using the control silicacolumn was 14.42 μg and the yield using the control SiC column was 13.68μg.

TABLE 4 Column Type Average Yield (μg) Standard Deviation SiC Control13.68 1.79 Hybrid D 19.97 1.26 Silica Control 14.42 0.36

Example 5

A different hybrid column was tested for its ability to isolate totalRNA from HeLa cell lysate. The hybrid column contains a bottom frit, 95mg of silicon carbide resin, and 2 layers of silica membrane with athickness of 1 mm each on top of the SiC resin (Hybrid B having thesolid support arrangement shown in FIG. 3). Control SiC columns werealso used that contained a bottom frit, 95 mg of 100% SiC slurry with agrit size of 2500, followed by a top frit.

One large confluent plate of HeLa cells was used for the input, and 9.1mL of the Lysis Solution from Norgen's Total RNA Purification Kit(Cat#17200, Norgen, Thorold, Canada) was added to the cells and it wasvortexed to mix. Next, 5.2 mL of ethanol was added, and again it wasvortexed to mix. Next, 550 μL of the lysate was applied to each of thecolumns (10×Hybrid B, 10×SiC control). The columns were centrifuged for1 minute at 14,000 rpm for binding of the nucleic acids. Next, 400 μL ofWash Solution from Norgen's Total RNA Purification Kit (Cat#17200,Norgen, Thorold, Canada) was added to each column, and the columns werespun at 14,000 rpm for 1 minute. The wash step was repeated two moretimes for a total of 3 washes. The columns were then spun empty for 2minutes at 14,000 rpm in order to dry the columns. Lastly, the boundtotal RNA was eluted from the columns using 50 μL of the ElutionSolution from the Total RNA Purification Kit (Cat#17200, Norgen,Thorold, Canada).

For visual analysis, 5 μL of each of the elutions was run on a 1×MOPS,1.5% formaldehyde-agarose gel (150V for 30 minutes). The gel image canbe seen in FIG. 12, indicating that the total RNA profile could beisolated using the hybrid columns, which is similar to the SiC controlcolumn (isolated both large and small RNA). Also, the overall yield oftotal RNA when using the hybrid column was much higher than when the SiCcontrol column was used.

To further analyze the yield, the RNA was quantified using a GE NanovuePlus Nanodrop. This analysis revealed the superior performance of thehybrid column. As it can be seen in Table 5, the average yield using thehybrid column was 19.7 μg, whereas the yield using the control SiCcolumn was 14.4 μg.

TABLE 5 Column Type Average Yield (μg) Standard Deviation Hybrid B 19.71.8 SiC Control 14.4 2.4

Example 6

A hybrid column (Hybrid C having the solid support arrangement shown inFIG. 6) was tested for its ability to isolate total RNA from hamsterliver FFPE tissue, and the performance was compared to control columnsof SiC alone. The hybrid column contain a bottom frit, followed by asingle layer of 1 mm silica membrane, 95 mg of silicon carbide resingrit size 2500, and another single layer of 1 mm silica membrane on topof the SiC resin. The control SiC columns contained a bottom frit, 95 mgof 100% SiC slurry with a grit size of 2500, followed by a top frit.

Two mg of unsectioned blocks of hamster liver FFPE tissue was used forthe input, and were trimmed of excess paraffin. The blocks were firstdeparaffinized by placing the blocks into microcentrifuge tubes, andadding 1 mL of xylene to the sample. The tubes were incubated at 50° C.for 5 minutes, followed by centrifugation and removal of the xylene.Next, the samples were washed with 1 mL of ethanol and air dried at roomtemperature. To prepare the lysate, 300 μL of Digestion Buffer fromNorgen's FFPE RNA Purification Kit (Cat#25300, Norgen, Thorold, Canada)and 10 μL of Proteinase K was to the sample, followed by incubation at55° C. for 15 minutes and incubation at 80° C. for 15 minutes. Next, 300μL of Binding Solution and 600 μL of ethanol was added. From this, 600μL of the lysate was applied to each of the columns (3×Hybrid C, 3×SiCcontrol). The columns were centrifuged for 1 minute at 14,000 rpm forbinding of the nucleic acids. Next, 400 μL of Wash Solution fromNorgen's FFPE RNA Purification Kit (Cat#25300 Norgen, Thorold, Canada)was added to each column, and the columns were spun at 14,000 rpm for 1minute. The wash step was repeated two more times for a total of 3washes. The columns were then spun empty for 2 minutes at 14,000 rpm inorder to dry the columns. Lastly, the bound total RNA was eluted fromthe columns using 50 μL of the Elution Solution from the FFPE RNAPurification Kit (Cat#25300, Norgen, Thorold, Canada).

To analyze the yield, the RNA was quantified using a GE Nanovue PlusNanodrop, and this analysis revealed the superior performance of thehybrid column. As it can be seen in Table 6, the average yield using thehybrid column was 5.3 μg, whereas the yield using the control SiC columnwas 4.2 μg.

TABLE 6 Column Type Average Yield (μg) Standard Deviation Hybrid C 5.30.2 SiC Control 4.2 0.5

To further analyze the performance of the hybrid column, the purifiedRNA was used in RT-qPCR reactions for the detection of both large RNAand microRNA. Briefly, for the reverse transcription 1 μg of thepurified RNA was used in a 20 μL reaction using Invitrogens SuperscriptIII System to generate the cDNA. Next, 3 μL of the cDNA was used in a 20μL SYBER Green qPCR reaction with specific primers for β-actin (largeRNA) and miR-30b and miR-21 (microRNAs). The following PCR program wasthen run for 40 cycles:

95° C. for 15 seconds

60° C. for 30 seconds

72° C. for 45 seconds

The Ct values from the RT-qPCR reactions were then analyzed, and theresults can be seen in Table 7. It was found that for the β-actin (largeRNA) and both miR-30b and miR-21 (small RNAs) the Ct values obtainedfrom the hybrid column were lower than the Ct values obtained from thecontrol SiC column. A lower Ct number indicates a higher starting amountof RNA. These results indicate that the increase in total RNA recoveryinvolves an increase in the recovery of all sizes of RNA. The increasein yield of small RNA when using the hybrid column when compared to theSiC control is not expected, as it is known that silica is not able toisolate small RNA molecules such as microRNA. Therefore, when using acombination of silica and SiC, it would not be expected that higherlevels of microRNA would be isolated than when using SiC alone. Theseresults clearly indicate the hybrid column provides an unexpected effectof higher yields of total RNA, and in particular small RNA, when silicaand SiC are used together.

TABLE 7 B-actin Ct Value miR-30b Ct Value miR-21 Ct Value ColumnStandard Standard Standard Type Average Deviation Average DeviationAverage Deviation Hybrid 24.4 0.0 19.6 0.8 14.1 1.1 C SiC 25.2 0.1 21.40.1 18.9 0.3 Control

The invention claimed is:
 1. A column for isolating nucleic acids, thecolumn comprising: a housing comprising an inlet opening and an outletopening; and a solid support disposed within the housing between theinlet and outlet openings, the solid support comprising silica andsilicon carbide, wherein: (a) the solid support comprises a plurality oflayers, each of the layers comprising the silica, the silicon carbide ora combination thereof and wherein at least two layers are different; or(b) the solid support comprises a mixture of the silica and the siliconcarbide in an approximately 1:1 weight ratio.
 2. The column of claim 1,wherein the solid support comprises: a first layer and second layer, thefirst and second layers being in a stacked orientation; and optionally,an intermediate layer disposed between the first and second layers;wherein (a) the first layer comprises the silicon carbide and the secondlayer comprises the silica; (b) the first layer comprises the silica andthe second layer comprises the silicon carbide; or (c) the first andsecond layers comprise the silica and the intermediate layer comprisesthe silicon carbide; wherein the silicon carbide is in the form ofsilicon carbide particles or a slurry of silicon carbide particles, andwherein the silica is in the form of silica particles, a slurry ofsilica particles, one or more silica membranes, or a combinationthereof.
 3. The column of claim 2, wherein the silica is in the form ofone or more silica membranes and each silica membrane has a thickness ofat least 0.5 mm.
 4. The column of claim 1, wherein the solid supportcomprises: a first layer and a second layer, the first and second layersbeing in a stacked orientation; and optionally, an intermediate layerdisposed between the first and second layers; wherein (a) the firstlayer comprises a plurality of silica membranes, wherein the siliconcarbide is deposited on a surface of at least one of the plurality ofsilica membranes and the second layer comprises at least one silicamembrane; (b) the first layer comprises at least one silica membrane andthe second layer comprise a plurality of silica membranes, wherein thesilicon carbide is deposited on a surface of at least one of theplurality of silica membranes; (c) the first layer and second layer eachcomprise a plurality of silica membranes, wherein the silicon carbide isdeposited on a surface of at least one of the plurality of silicamembranes and the intermediate layer comprises at least one silicamembrane; or (d) the first layer and second layer each comprise at leastone silica membrane and the intermediate layer comprises a plurality ofsilica membranes, wherein the silicon carbide is deposited on a surfaceof at least one of the plurality of silica membranes.
 5. The column ofclaim 4, wherein each silica membrane has a thickness of at least 0.5mm.
 6. The column of claim 1, wherein the solid support comprises: afirst layer and a second layer, the first and second layer being instacked orientation; and an intermediate layer disposed between thefirst and second layers; wherein (a) the first layer comprises at leastone silica membrane, the second layer comprise silica particles, and theintermediate layer comprises silicon carbide particles; (b) the firstlayer comprises at least one silica membrane, the second layer comprisesilicon carbide particles, and the intermediate layer comprises silicaparticles; (c) the first layer comprises silicon carbide particles, thesecond layer comprises at least one silica membrane, and theintermediate layer comprises silica particles; (d) the first layercomprises silica particles, the second layer comprises at least onesilica membrane, and the intermediate layer comprises silicon carbideparticles; (e) the first layer and second layer each comprise siliconcarbide particles and the intermediate layer comprises silica particles;or (f) the first layer and second layer each comprise silicon carbideparticles and the intermediate layer comprises at least one silicamembrane.
 7. The column of claim 6, wherein the first layer comprises atleast one silica membrane, the second layer comprise silica particles,and the intermediate layer comprises silicon carbide particles; andwherein the at least one silica membrane has a thickness of at least 0.5mm.
 8. The column of claim 6, wherein the first layer comprises at leastone silica membrane, the second layer comprise silicon carbideparticles, and the intermediate layer comprises silica particles; andwherein the at least one silica membrane has a thickness of at least 0.5mm.
 9. The column of claim 6, wherein the first layer comprises siliconcarbide particles, the second layer comprises at least one silicamembrane, and the intermediate layer comprises silica particles; andwherein the at least one silica membrane has a thickness of at least 0.5mm.
 10. The column of claim 6, wherein the first layer comprises silicaparticles, the second layer comprises at least one silica membrane, andthe intermediate layer comprises silicon carbide particles; and whereinthe at least one silica membrane has a thickness of at least 0.5 mm. 11.The column of claim 6, wherein the first layer and second layer eachcomprise silicon carbide particles and the intermediate layer comprisesat least one silica membrane; and wherein the at least one silicamembrane has a thickness of at least 0.5 mm.
 12. The column of claim 1,wherein the mixture is a mixture of silicon carbide particles and silicaparticles.
 13. The column of claim 12, wherein the mixture of silicaparticles and silicon carbide particles is in the form of a slurry. 14.The column of claim 1, wherein the column is a spin column.